# Copyright 2022 The KerasCV Authors
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
#     https://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.

import numpy as np
import pytest
import tensorflow as tf
from tensorflow import keras
from tensorflow.keras import layers
from tensorflow.keras import metrics
from tensorflow.keras import optimizers

from keras_cv.src.layers import preprocessing
from keras_cv.src.losses import SimCLRLoss
from keras_cv.src.models import DenseNet121Backbone
from keras_cv.src.tests.test_case import TestCase
from keras_cv.src.training import ContrastiveTrainer


# TODO(jbischof): revisit "extra_large" tag once development resumes.
# These tests are currently some of the slowest in our repo.
@pytest.mark.extra_large
class ContrastiveTrainerTest(TestCase):
    def test_probe_requires_probe_optimizer(self):
        trainer = ContrastiveTrainer(
            encoder=self.build_encoder(),
            augmenter=self.build_augmenter(),
            projector=self.build_projector(),
            probe=self.build_probe(),
        )
        with self.assertRaises(ValueError):
            trainer.compile(
                encoder_optimizer=optimizers.Adam(),
                encoder_loss=SimCLRLoss(temperature=0.5),
            )

    def test_targets_required_if_probing(self):
        trainer_with_probing = ContrastiveTrainer(
            encoder=self.build_encoder(),
            augmenter=self.build_augmenter(),
            projector=self.build_projector(),
            probe=self.build_probe(),
        )
        trainer_without_probing = ContrastiveTrainer(
            encoder=self.build_encoder(),
            augmenter=self.build_augmenter(),
            projector=self.build_projector(),
            probe=None,
        )

        images = tf.random.uniform((1, 50, 50, 3))

        trainer_with_probing.compile(
            encoder_optimizer=optimizers.Adam(),
            encoder_loss=SimCLRLoss(temperature=0.5),
            probe_optimizer=optimizers.Adam(),
            probe_loss=keras.losses.CategoricalCrossentropy(from_logits=True),
        )
        trainer_without_probing.compile(
            encoder_optimizer=optimizers.Adam(),
            encoder_loss=SimCLRLoss(temperature=0.5),
        )

        with self.assertRaises(ValueError):
            trainer_with_probing.fit(images)

    def test_train_with_probing(self):
        trainer_with_probing = ContrastiveTrainer(
            encoder=self.build_encoder(),
            augmenter=self.build_augmenter(),
            projector=self.build_projector(),
            probe=self.build_probe(num_classes=20),
        )

        images = tf.random.uniform((1, 50, 50, 3))
        targets = np.ones((1, 20))

        trainer_with_probing.compile(
            encoder_optimizer=optimizers.Adam(),
            encoder_loss=SimCLRLoss(temperature=0.5),
            probe_metrics=[
                metrics.TopKCategoricalAccuracy(3, "top3_probe_accuracy")
            ],
            probe_optimizer=optimizers.Adam(),
            probe_loss=keras.losses.CategoricalCrossentropy(from_logits=True),
        )

        trainer_with_probing.fit(images, targets)

    def test_train_without_probing(self):
        trainer_without_probing = ContrastiveTrainer(
            encoder=self.build_encoder(),
            augmenter=self.build_augmenter(),
            projector=self.build_projector(),
            probe=None,
        )

        images = tf.random.uniform((1, 50, 50, 3))
        targets = np.ones((1, 20))

        trainer_without_probing.compile(
            encoder_optimizer=optimizers.Adam(),
            encoder_loss=SimCLRLoss(temperature=0.5),
        )

        trainer_without_probing.fit(images)
        trainer_without_probing.fit(images, targets)

    def test_inference_not_supported(self):
        trainer = ContrastiveTrainer(
            encoder=self.build_encoder(),
            augmenter=self.build_augmenter(),
            projector=self.build_projector(),
            probe=None,
        )
        trainer.compile(
            encoder_optimizer=optimizers.Adam(),
            encoder_loss=SimCLRLoss(temperature=0.5),
        )

        with self.assertRaises(NotImplementedError):
            trainer(np.ones((1, 50, 50, 3)))

    def test_encoder_must_have_flat_output(self):
        with self.assertRaises(ValueError):
            _ = ContrastiveTrainer(
                # A DenseNet without pooling does not have a flat output
                encoder=DenseNet121Backbone(include_rescaling=False),
                augmenter=self.build_augmenter(),
                projector=self.build_projector(),
                probe=None,
            )

    def test_with_multiple_augmenters_and_projectors(self):
        augmenter0 = preprocessing.RandomFlip("horizontal")
        augmenter1 = preprocessing.RandomFlip("vertical")

        projector0 = layers.Dense(64, name="projector0")
        projector1 = keras.Sequential(
            [projector0, layers.ReLU(), layers.Dense(64, name="projector1")]
        )

        trainer_without_probing = ContrastiveTrainer(
            encoder=self.build_encoder(),
            augmenter=(augmenter0, augmenter1),
            projector=(projector0, projector1),
            probe=None,
        )

        images = tf.random.uniform((1, 50, 50, 3))

        trainer_without_probing.compile(
            encoder_optimizer=optimizers.Adam(),
            encoder_loss=SimCLRLoss(temperature=0.5),
        )

        trainer_without_probing.fit(images)

    def build_augmenter(self):
        return preprocessing.RandomFlip("horizontal")

    def build_encoder(self):
        return keras.Sequential(
            [
                DenseNet121Backbone(include_rescaling=False),
                layers.GlobalAveragePooling2D(name="avg_pool"),
            ],
        )

    def build_projector(self):
        return layers.Dense(128)

    def build_probe(self, num_classes=20):
        return layers.Dense(num_classes)
